Photoinduced in situ generation of DNA-targeting ligands: DNA-binding and DNA-photodamaging properties of benzo[c]quinolizinium ions

The photoreactions of selected styrylpyridine derivatives to the corresponding benzo[c]quinolizinium ions are described. It is shown that these reactions are more efficient in aqueous solution (97–44%) than in organic solvents (78–20% in MeCN). The quinolizinium derivatives bind to DNA by intercalation with binding constants of 6–11 × 104 M−1, as shown by photometric and fluorimetric titrations as well as by CD- and LD-spectroscopic analyses. These ligand–DNA complexes can also be established in situ upon irradiation of the styrylpyridines and formation of the intercalator directly in the presence of DNA. In addition to the DNA-binding properties, the tested benzo[c]quinolizinium derivatives also operate as photosensitizers, which induce DNA damage at relative low concentrations and short irradiation times, even under anaerobic conditions. Investigations of the mechanism of the DNA damage revealed the involvement of intermediate hydroxyl radicals and C-centered radicals. Under aerobic conditions, singlet oxygen only contributes to marginal extent to the DNA damage.


Introduction
DNA intercalators -most often represented by small planar heteroaromatic compounds -play an important role as chemotherapeutic agents [1][2][3][4].Specifically, upon intercalation into the DNA double helix such ligands can cause a change of the DNA structure or occupy binding sites of essential enzymes, which in turn may influence or even inhibit important biochem-ical processes, for example DNA replication or transcription [1,2].As a result, the development of DNA-targeting drugs still involves the design of suitable DNA intercalators, and some currently applied anticancer drugs actually operate on the basis of intercalation [3].Hence, several classes of compounds have been established, whose DNA-binding properties can be Scheme 1: Photoinduced formation of benzo[c]quinolizinium and its interaction with DNA upon intercalation.
In this context, benzoquinolizinium derivatives and resembling polycyclic azoniahetarenes are an established class of DNAbinding compounds, which have been employed in biomedical imaging and as potential DNA-targeting anticancer agents [14][15][16][17].More recently, a benzoquinolizinium-based fluorescent dye was reported to be used as imaging agent for inflammation and for the evaluation of the physiological response to anti-inflammatory drugs [18].
In this context, the benzo[c]quinolizinium structure provides some special features.First of all, it has the general requirements of a DNA intercalator, namely a planar, polycyclic heteroaromatic structure and a permanent positive charge [14].Moreover, it has been shown that this DNA-binder and resembling intercalators can be directly generated upon irradiation of styrylazines under aerobic conditions, even in the presence of DNA, which provides local and temporal control of the DNAbinding event (Scheme 1) [14].Specifically, the styrylpyridine, which does not bind to DNA, can be delivered without effect to the binding site, where the DNA-binding benzoquinolizinium ligand can then be generated as needed upon irradiation.Notably, the use of light for the activation of photo-controllable DNA ligands offers several advantages because it is easy to apply, traceless, and non-invasive [19].As a result, several photoactive compounds have been developed, whose DNAbinding properties can be efficiently switched on and off by light [14,[20][21][22][23][24][25][26][27][28][29][30][31][32][33][34].
In addition to their DNA-binding properties some annelated quinolizinium derivatives have also the ability to induce DNA damage upon irradiation [35][36][37][38], and may therefore be considered as promising basis for the development of new reagents for photodynamic (chemo)therapy (PDT).Notably, PDT has de-veloped into an important therapeutic tool against several serious diseases, such as cancer [39], and bacterial, fungal, parasitic and viral infections [40,41].In general, PDT operates on the basis of a photosensitizer, which generates reactive intermediates upon irradiation [42][43][44][45].Hence, in the type-I mechanism the photosensitizer induces the formation of reactive oxygen species (ROS), such peroxyl, alkoxy and hydroxyl radicals, or carbon-centered radicals, which subsequently induce DNA strand cleavage.In the type-II mechanism, a tripletexcited photosensitizer reacts with molecular oxygen to give highly reactive singlet oxygen, 1 O 2 , as reactive intermediate, which in turn oxidizes the DNA bases [46].As a result, various classes of photosensitizers [47][48][49] have been established, for example, porphyrins [50], chlorins [51], phthalocyanines [52], porphycenes [53], metal-organic complexes [54][55][56], dye aggregates [57], as well as nano-drug carriers and metal-based nanoparticles [58,59].But although these classes of compounds have been intensively studied and already contributed significantly to the field of PDT, there is still a demand for novel DNA-photodamaging ligands that could be applied for specific purposes, e.g., to improve efficacy or to limit side-effects.Therefore, the search for a class of photosensitizers is still a topical research area in photobiology [60].To this end, benzo[c]quinolizinium derivatives may be considered as feasible photosensitizers because they can be formed readily in situ in the presence of DNA and because the structurally related alkaloids berberine [61][62][63][64][65] and coralyne [36,66,67] have been shown already to act as efficient photosensitizers for DNA damage.To the best of our knowledge, however, benzo[c]quinolizinium derivatives have not been investigated with respect to their DNA-photodamaging properties, so far.Therefore, we have synthesized selected benzo[c]quinolizinium derivatives and studied their DNA-binding and DNA-photodamaging properties.

Synthesis
The styrylpyridine derivatives 2a,c,d,f were synthesized by a piperidine-or Ca(OTf) 2 -catalyzed condensation reaction of 3,4dimethoxybenzaldehyde with 5-substituted 2-picoline deriva-  tives in low to moderate yields ranging from 13% (2f) to 65% (2a) (Scheme 2).The amino-substituted derivative 2b was synthesized by reduction of the nitrostyrylpyridine 2a with Pd/C and hydrazine in 83% yield.Subsequent acylation of the amine 2b gave the corresponding amide 2g in 28% yield.The chlorosubstituted derivative 2e was synthesized in a Sandmeyer-reaction from 2b in 20% yield.The products 2a-g were identified and fully characterized by NMR spectroscopy ( 1 H, 13 C, COSY, HSQC, and HMBC), elemental analyses, and mass spectrometry.In all cases, the E-configuration of the alkene double bonds was indicated by characteristic coupling constants of the alkene protons ( 3 J H-H = 16 Hz).

Absorption properties and photoreactions of styrylpyridine derivatives
In acetonitrile solution, the styrylpyridines 2a-g exhibited longwavelength absorption bands with maxima in a range from λ max = 333 nm for the ethyl-substituted compound 2f to λ max = 394 nm for the nitro-substituted derivative 2a (Figure 1A, Supporting Information File 1, Table S1).As com-pared with the absorption maximum of the parent compound at λ max = 330 nm [20], the derivatives 2b-g showed a slight bathochromic shift mostly in the range of λ max = 333-360 nm, whereas for the nitro-substituted compound 2a a stronger red shift of the absorption maximum was observed, presumably caused by the strong electron-withdrawing property of the nitro group resulting in a more pronounced intramolecular charge transfer [68].In water, the absorption maxima showed only a small shift of the absorption maxima of 1-4 nm as compared with the ones in acetonitrile (Figure 1B, Supporting Information File 1, Table S1).The absorption spectra of compounds 2a and 2c could not be recorded because of their low water solubility.
The styrylpyridine derivatives 2a-g were irradiated in oxygensaturated solutions in MeCN, H 2 O, MeOH, or MeCN/H 2 O with a high-pressure Hg lamp (λ > 220 nm), and the course of the photocyclization reaction was monitored by absorption spectroscopy (Figure 2).In general, the absorption maximum of the derivatives 2b-g decreased during the photoreaction with for- mation of new red-shifted absorption bands.Nevertheless, the new red-shifted absorption band of the amino-substituted styryl derivative 2b in MeCN was weak and very broad, indicating only negligible formation of the photocyclization product (Figure 2B).Likewise, in H 2 O solution with MeCN as co-solvent, no formation of a new absorption band was observed upon irradiation of 2b, either (Figure 2C).Moreover, the aminobenzoquinolizinium 3b could not be isolated after irradiation of 2b at larger scale.As an exception, the irradiation of the nitrosubstituted styrylpyridine derivative 2a in MeCN or H 2 O led to disappearance of the long-wavelength absorption maximum with no formation of a distinct new band (Figure 2A), which usually indicates photoinduced decomposition.This observation is in agreement with reports on resembling aromatic p-nitro-substituted derivatives, which do not react in a photocyclization reaction [69].
Direct irradiation of the styrylpyridine derivatives 2c-g in MeCN led to the formation of new absorption bands in the range from λ = 389 nm (2f) to λ = 407 nm (2d) with bathochromic shifts of Δλ = 47-57 nm (Figure 3, Supporting Information File 1, Table S1), which indicated the formation of the benzo[c]quinolizinium ions 3c-g as photocyclization products [20].The absence of isosbestic points during the photometric monitoring of the photoreactions indicated a stepwise formation of different intermediates in the reaction sequence starting with E-Z isomerization, followed by photocyclization and subsequent oxidation.
In general, the photoreaction was more efficient in polar, protic aqueous solvents (cf.Supporting Information File 1, Figures S2B-S6B) or in buffer solution (cf.Supporting Information File 1, Figures S3C-S6C) than in polar, aprotic MeCN solution.In MeOH the photoreactions were inefficient as indicated by the lack of red-shifted bands or by formation of broad, weak absorption bands (cf.Supporting Information File 1, Figures S1, S2A, S3A, S4A, S5A, and S6A).Because of the low water solubility of the styrylpyridine derivatives 2a-g, solvent mixtures of MeCN/H 2 O or pure MeCN were used for the preparative photocyclization reactions (Scheme 3, cf.Supporting Information File 1, Figure S2C,D) to provide sufficient solubility of the substrates, as well as optimal efficiencies for the formation of photocyclization products.But even under these optimized conditions, compounds 3c-g could be isolated only in low yields of <5-21%.Hence, to assess whether the products are generally formed to minor extent in the photoreaction or whether the low yields of isolated product result from significant losses during the purification process, the content and yield of the benzo[c]quinolizinium ions were determined directly after irradiation of 2c, 2e-g by photometric analysis of the reaction mixture (Figure 3, red spectra).The yield of the product 3d could not be determined because it was not available in pure form on preparative scale.With the absorption data, specifically the molar extinction coefficients, obtained from the isolat- ed benzo[c]quinolizinium derivatives, the yields of the initially formed photoproducts 3c, 3e, 3f, and 3g in the reaction mixtures were determined to be 78%, 73%, 30%, and 20% in MeCN, >97%, 80%, 44% and 55% in H 2 O, and 32%, 76%, 53% and 38% in Na phosphate buffer.Overall, the initially formed amounts of photoproducts are significantly larger than the ones of the isolated compounds, in the case of 3c and 3e even with good yields, so that it may be concluded that the small amounts of isolated product result from losses during work-up and purification.

DNA-binding properties of benzoquinolizinium derivatives 3c,e-g
The styrylpyridines 2d-g and the benzo[c]quinolizinium derivatives 3c,e-g were investigated with respect to their DNAbinding properties with calf thymus (ct) DNA.The titrations of ct DNA to compounds 2d-g resulted in no or only negligible changes of the absorption and fluorescence spectra (cf.Supporting Information File 1, Figures S8-S11), indicating that these substrates do not interact significantly with DNA.In contrast, upon addition of DNA to compounds 3c,e-g, the absorption maxima at 398 nm, 393 nm, 386 nm and 394 nm were redshifted with a hypochromic effect, and isosbestic points developed during all titrations (Figure 4, Table 1).Furthermore, the addition of DNA to substrates 3c,e-g led to efficient fluorescence quenching (Figure 5), which is commonly observed  with this class of cationic ligands [3,70], mainly as a result of a photoinduced electron transfer from the excited, DNA-bound ligand with the DNA bases [71].The binding isotherms obtained from the titration data were used to determine the binding constants, K b , of the DNA ligands.Thus, the derivatives 3c, 3e, and 3g bind to ct DNA with K b values of 6.0 × 10 4 M −1 , 5.9 × 10 4 M -1 , and 6.4 × 10 4 M −1 , respectively, whereas the affinity of ligand 3f is slightly higher with K b = 1.1 × 10 5 M −1 , which is in the same range as the binding constant reported for the 8,9-dimethoxybenzo[c]quinolizinium (K b = 1.2 × 10 5 M −1 ) [20].The slightly lower binding constants of derivatives 3c, 3e, and 3g as compared with the one of compound 3f, may be explained by the larger substituents of the former ligands, which cause more steric repulsion within the binding site.
The binding mode of the benzo[c]quinolizinium derivatives 3c,e-g with DNA was further examined with circular dichroism (CD) and linear dichroism (LD) spectroscopy (Figure 6 and Supporting Information File 1, Figures S12-S14).Hence, with increasing ligand-DNA ratio (LDR) weak positive induced CD (ICD) signals developed in the long-wavelength absorption range of ligands 3e-g, that is, where the DNA bases do not absorb (Figure 6A and Supporting Information File 1, Figures S13A and S14A), which is a commonly observed indication of DNA binding as the ICD bands result from non-degenerative coupling of the dipole moments of the ligand with the DNA bases [72].The association of the ligands 3e-g with DNA was further confirmed by the formation of negative LD bands with increasing LDR developing in the absorption range of the ligands (λ > 300 nm) (Figure 6B and Supporting Information File 1, Figures S13B and S14B), which is a characteristic indication of a coplanar alignment of the ligand relative to the base pairs in an intercalative binding mode [73].In contrast, ligand 3c did not exhibit an ICD signal in the presence of DNA (Supporting Information File 1, Figure S12A) and gave rather weak and less structured LD bands (Figure S12B) as compared with the ones of ligands 3e-g.The lack of distinct ICD bands of DNA-bound 3c might be explained by the very weak signals, which are usually observed for this class of DNA binder because of unfavorable angles between transition moments of ligand and DNA bases [72].
To gain additional information about the orientation of the benzo[c]quinolizinium ligand in the intercalation site, the reduced LD (LD r ) spectrum was determined exemplarily for ligand 3f (Supporting Information File 1, Figure S15) [74,75].The analysis of the data revealed a binding angle α = 59° between the ligand 3f and the DNA helix, thus indicating a tilted orientation of the ligand relative to the DNA base pairs within the binding site.
The DNA-binding ligands were also generated in situ in the presence of DNA.For that purpose, solutions of the styrylpyridines 2d-g and ct DNA were irradiated in phosphate buffer, and the formation of the dimethoxybenzo[c]quinolizinium ions and their subsequent binding to the DNA were shown photometrically by the development of the characteristic red-shifted absorption bands (Figure 7A, cf.Supporting Information File 1, Figure S7A), which matched the ones of the independently formed complexes of these ligands with DNA (see above).In the case of 3e-g, the binding event was also confirmed by CD spectroscopy, namely by the formation of weak ICD signals (Figure 7B, cf.Supporting Information File 1, Figure S7B).Because of the very low solubility of compound 2c in aqueous solutions, the former could not be irradiated in situ in the presence of DNA.

Photoinduced DNA damage
In first orienting experiments, the photoinduced DNA damage by benzo[c]quinolizinium derivatives was examined exemplarily with ligand 3f and plasmid DNA pBR322 (Table 2).To assess the optimal parameters for the photoreaction, the ligand was irradiated in the presence of the DNA under anaerobic conditions at different irradiation times and concentrations of the ligand.The DNA-strand cleavage was analyzed by agarosegel electrophoresis.In this assay, the DNA-strand cleavage in the supercoiled plasmid DNA pBR322 is indicated by the formation of the relaxed, open-circular form [76].It has to be noted that under these conditions the DNA is already damaged in the absence of the photosensitizer.Therefore, each series of experiments is complemented for comparison with control experiments without photosensitizer.In general, a photoinduced DNA damage by the quinolizinium 3f was observed, whose extent increased with increasing irradiation time and with increasing concentration of 3f.Thus, after 2 min of irradiation with fixed concentration (c = 2.5 × 10 −5 M) 38% of the supercoiled DNA were transformed to the open-circular form, whereas after 5 min, 73% of the DNA were damaged by strand cleavage (Table 2A).At the same time, experiments with varying ligand concentration revealed 81% of damaged DNA after 2 min of irradiation with c = 5.0 × 10 −5 M, which was almost twice as much as the cleavage (41%) determined with c = 2.5 × 10 −5 M Table 2B).In addition, a small series of benzo[c]quinolizinium ligands 3c,e-g was tested under conditions optimized for derivative 3f.Within this series, the amount of DNA cleavage ranged fom 39% (3c) to 51% (3e) after 2 min of irradiation (Table 2C).
To investigate the mechanism of the DNA cleavage, commonly employed control experiments [46,77] were performed exemplarily with ligand 3f (Table 3 and Supporting Information File 1, Figure S16).To assess the influence of oxygen, the DNA-ligand mixture was irradiated for 2 min under ambient aerobic conditions as well as in argon-and oxygen-saturated medium (Supporting Information File 1, Figure S16A).Under anaerobic atmosphere, 50% of the supercoiled DNA were transformed to open-circular DNA after 2 min of irradiation, whereas under atmospheric conditions and oxygen-saturation only 36% and 30% of the DNA were cleaved, respectively.However, with prolonged irradiation time, even under oxygen atmosphere the photocleavage activity increased to give 65% strand cleavage after 5 min and 85% after 10 min of irradiation (Supporting Information File 1, Figure S16B).
To clarify whether the mechanism of the DNA photodamage proceeds through the formation of radicals, experiments with commmonly employed radical scavengers were conducted (Table 3, Supporting Information File 1, Figure S17).In the presence of hydroxyl-radical scavengers DMSO, t-BuOH, and 2-propanol [78] the cleavage of the DNA was reduced to 34%, 28%, and 23%, respectively, which may indicate that the cleavage of DNA involves hydroxyl radicals (Supporting Information File 1, Figure S17A).At the other hand, a clear decrease of DNA damage to ca. 13%, 18% and 16% in the presence of 2,2,6,6-tetramethylpiperidine 1-oxyl (TEMPO), 2-mercaptoethanol and 2-mercaptoethylamine hydrochloride, respectively, showed that C-centered radicals contribute even more to the DNA damage than hydroxyl radicals (Supporting Information File 1, Figure S17B).It should be noted, however, that these scavengers may also intercept hydroxyl radicals [79] or interfere with the DNA damage by alternative pathways [80].In any case, the significant decrease of DNA damage in the presence of the radical scavengers indicated the formation and direct or indirect participation of carbon radicals and hydroxyl radicals in the photoinduced DNA damage.
In order to investigate the involvement of singlet oxygen in the DNA cleavage process, the samples were irradiated in the presence of NaN 3 or in D 2 O (Table 3, Supporting Information File 1, Figure S18).The latter is known to extend the lifetime of singlet oxygen by a factor of ca. 10 as compared with H 2 O.   cleavage to 17%.It has to be noted, however, that an inhibition of DNA cleavage in the presence of NaN 3 may also be induced by direct deactivation of the excited photosensitizer by the azide and not only from quenching of singlet oxygen [83].Similar, seemingly contradictory effects of D 2 O and NaN 3 on the photoinduced DNA cleavage were observed with other photosensitizers [84,85].In addition, it has been reported that a relative large excess of NaN 3 is required to detect an efficient inhibition of DNA-photocleavage [86].Overall, these results as well as the efficient photocleavage under oxygen-saturated conditions, at least with long irradiation times (Supporting Information File 1, Figure S18B), indicated the direct or indirect involvement of singlet oxygen in the overall mechanism; yet, only to a small extent.
Overall, the experiments on the photoinduced DNA damage by benzo[c]quinolizinium 3f revealed a more complex mechanistic scenario (Scheme 4).While it became clear that the irradiation of this substrate in the presence of DNA leads to efficient DNA-strand cleavage, the systematic assessment of parameters that influence this reaction revealed the formation of different reactive intermediates (Scheme 4).Under anaerobic conditions, the DNA damage is similar to the one observed with the isomeric benzo[c]quinolizinium ions [35].In the latter case, it has been shown that frank DNA-strand breaks are induced by hydroxyl radicals, supposedly formed by photoinduced electron transfer (PET) reaction of the strongly oxidizing excited quinolizinium ion.Likewise, the results obtained with 3f point to the formation of hydoxyl radicals that are known to induce DNA-strand breaks.At the same time, the formation of C-centered radicals was indicated by the pronounced decrease of photocleavage in the presence of the corresponding radical scavengers.As there is no obvious reaction mechanism for the direct formation of C-radicals upon irradiation of 3f it is proposed that the reaction of the initially formed hydroxyl radicals with the benzoquinolizinium 3f leads to the formation of the C-centered radicals 4 and 5, namely by addition of the radical or by hydrogen abstraction at the methylene group of the ethyl substituent (Scheme 4).Subsequently, the intermediate radicals 4 and 5 induce DNA-strand breaks initiated by hydrogen abstraction reactions at the ribose residues [78,87].
Most notably, under aerobic conditions, a reduced DNA photocleavage was observed as compared with the reaction under anaerobic conditions.This result is somewhat surprising as the formation of singlet oxygen, 1 O 2 , by the reaction of the tripletexcited 3f and oxygen was confirmed in control experiments.And the reactive intermediate 1 O 2 is known to induce DNA damage [78,88].Nevertheless, these lesions, namely DNA base oxidations, often require alkaline treatment to lead to a strand cleavage, so that the DNA damage remained mainly unnoticed in the employed assay.At the same time, it has been reported that 1 O 2 can also efficiently induce single-strand breaks directly [89], so that the observed low DNA cleavage under aerobic conditions may be assigned to such a reaction.Moreover, it should be noted that both 3 O 2 and 1 O 2 [46] might react with other intermediates formed during the photoreaction, for example by the reaction with C-radicals 4 and 5 to give peroxides such as 6 (Scheme 4), by cycloaddition of 1 O 2 to alkene and diene units, or by deactivation of the excited state in a triplettriplet annihilation [90], all of which leading to a reduced photocleavage efficiency.However, with much longer irradiation time under oxygen-saturated conditions, a more efficient photodamage was observed, which may be induced by those intermediates or secondary products formed from these 1 O 2 reactions.
In comparison with the already known quinolizinium-type photosensitizers [35,91], the photoinduced DNA damage by benzo[c]quinolizinium derivatives is more efficient under resembling conditions.Thus, the isomeric benzo[b]quinolizinium cations showed DNA damage to a lower extent after irradiation for 10 min with 15-20% and 20-25% DNA cleavage under anaerobic and aerobic conditions, respectively [35].Likewise, naphthoquinolizinium salts exhibited DNA cleavage of about 20% and 50% after 5 min and 10 min, respectively, under anaerobic conditions, thus showing lower efficiencies as compared with photosensitizer 3f with DNA cleavage of 73% and 83%, respectively [91].

Conclusion
In summary, it was demonstrated that the photoinduced cyclization reaction of readily available styrylpyridine derivatives 2a-g gives the corresponding benzo[c]quinolizinium derivatives and that these reactions are more efficient in aqueous solutions than in organic solvents.The benzo[c]quinolizinium derivatives have the typical properties of DNA intercalators and bind to DNA with K b values of 6.0-11 × 10 4 M -1 .Importantly, the ligand-DNA complex may be accessed as needed in situ upon irradiation of the styrylpyridines 2c,e-g in the presence of DNA, which is a useful feature of DNA-targeting substrates, specifically for a spatio-temporal control of this biological activity.
Furthermore, we have discovered that this class of compounds has a large potential to operate as photosensitizer that induces DNA damage already at relatively low irradiation times and low concentrations.Most notably, the photoinduced DNA damage does not necessarily require oxygen, unlike type-II photosensitizers.In fact, the representative compound 3f is a more efficient DNA-damaging photosensitizer under anaerobic conditions, which may be an advantage for applications in hypoxic cancer cells.Preliminary investigations of the mechanism of the DNA damage revealed the involvement of intermediate hydroxyl radicals and C-centered radicals.Singlet oxygen, one of the most important reactive intermediates in conventional PDT, however, only contributes to marginal extent to the DNA damage.Therefore, these results are a promising starting point for the development of novel photosensitizers based on benzo[c]quinolizinium derivatives because their particular mode of activity may offer complementary applications in addition to the already established photosensitizers.
Overall, the benzo[c]quinolizinium scaffold offers some advantageous properties for its use as DNA-targeting agent, both as photo-controllable DNA binder and as DNA-damaging photosensitizer.Still, some key parameters have to be optimized by variation of the substitution pattern.For example, the water solubility of the styrylpyridine substrates has to be increased, and the excitation wavelength for the photocyclization reaction has to be red-shifted.But with a focus on the improvement of these properties the benzo[c]quinolizinium ion should be considered as a promising platform for further development of DNA-binding and DNA-photodamaging reagents.

Experimental General methods
The commercially available chemicals (Alfa, Merck, Fluorochem or BLDpharm) were of reagent grade and used without further purification.

Synthesis General procedure (GP)
A solution of the styrylpyridine derivatives (c = 0.24-0.95mM) in MeCN or in a mixture of MeCN/H 2 O was saturated with oxygen gas for 5-15 min, and the solutions were irradiated in an immersion-well photoreactor with a high-pressure Hg lamp.The reaction was controlled by absorption spectroscopy.After completion of the reaction, the solvent was removed by distillation, and the residue was purified by washing with n-pentane, n-hexane or n-hexane and EtOAc and subsequently by column chromatography or recrystallization from MeOH with addition of HClO 4 .

Figure 2 :
Figure 2: Changes of the absorption spectra during the irradiation of 2a in MeCN for 16 min (A), 2b in MeCN for 4 min (B), and 2b in H 2 O/MeCN 49:1 for 6 min (C) (c = 20 µM, λ ex > 220 nm, irradiated in a cuvette).Blue: spectrum of the starting material before irradiation; red: spectrum at the end of the irradiation.

Figure 3 :
Figure 3: Changes of the absorption spectra during the irradiation of 2c for 13 min (A), 2d for 12 min (B), 2e for 15 min (C), 2f for 10 min (D), and 2g for 7 min (E) (in MeCN, c = 20 µM, λ ex > 220 nm, irradiated in a cuvette).Blue: spectrum of the starting material before irradiation; red: spectrum at the end of the irradiation.

Figure 7 :
Figure 7: Changes of the absorption (A) and CD (B) spectra during the irradiation of 2e (1) and 2f (2) (c = 20 μM) in the presence of ct DNA (c DNA = 0.1 mM) in Na phosphate buffer, c Na+ = 16 mM.Blue: spectrum of the starting material before irradiation; red: spectrum at the end of the irradiation.

Table 2 :
Gel-electrophoretic analysis of photoinduced DNA-strand cleavage in the presence of 3f depending on the irradiation time (A), on the concentration (B), and in the presence of 3c,e-g (C).Lanes 1, 10 and 11 (A) and lane 11 (B): control experiment without 3f.Lanes 1 and 2 (B): control experiment without 3f, irradiated for 2 min.In all cases: c 3 = 2.5 × 10 −5 M, c DNA = 3.5 × 10 −9 Therefore, strand cleavage reactions induced by singlet oxygen are more efficient in D 2 O than in H 2 O[81].However, irradiation of 3f in D 2 O resulted in essentially the same DNA cleavage (23%) as compared with the reaction in H 2 O (25%) under otherwise identical conditions (Supporting Information File 1, FigureS18A).In the presence of NaN 3 (2.5 × 10 −5 M), which is a known radical scavenger for singlet oxygen[82], a strand cleavage of 25% occurred, whereas 38% cleavage was observed in the absence of NaN 3 .Nevertheless, a larger access of the scavenger (2.5 × 10 −4 M) resulted in a decrease of the

Scheme 4 :
Scheme 4: Proposed mechanisms for the photoinduced DNA damage initiated by photoexcitation of benzoquinolizinium 3f.

Table 1 :
Absorption and emission maxima of 3c-g in the absence and presence of ct DNA and binding constants of their complexes with ct DNA.Na+ = 16 mM, pH 7.0, 20 °C.b Determined from photometric titrations.
a In Na phosphate buffer, c